[0001] This invention relates to apparatus for urging an axially movable member to a neutral
axial position and it relates more particularly to such apparatus when used in an
optical pickup so as to retain the neutral point of focusing in equipment in which
focusing and tracking are performed by sliding a lens in the axial direction and by
rotating it about a shaft, respectively.
[0002] An optical pickup is known in which focusing and tracking are performed by sliding
a lens in the axial direction and by rotating it about a shaft, respectively. In such
apparatus, it is common to use a rubber spring as a focusing spring.
[0003] This known method of retention by a rubber spring, however, requires the provision
of space for the rubber spring, and is therefore very inconvenient from the viewpoint
of the desirability of reducing the size of the pickup.
[0004] Moreover, if the rubber spring is inaccurately mounted in such a way that it is distorted,
non-linearity may be generated in the spring action.
[0005] In addition, the rubber spring does not have good temperature characteristics due
to the physical properties of its material, and it deteriorates as its resonance frequency
or sensitivity changes.
[0006] In JP-A-59-229,750 there is disclosed an apparatus for urging an axially movable
member towards a neutral axial position comprising an axially movable member which
is axially movable over a shaft; coil means mounted on the axially movable member
for adjusting the axial position of the latter; and magnetic circuit means for generating
a magnetic field in which the coil means is positioned, the axially movable member
being provided with pieces of magnetic material which are disposed in said magnetic
field so that the latter exerts a force which urges the axially movable member towards
a neutral axial position.
[0007] According to the present invention, there is provided apparatus for urging an axially
movable member towards a neutral axial position comprising an axially movable member
which is axially movable over a shaft; coil means mounted on the axially movable member
for adjusting the axial position of the latter; and magnetic circuit means for generating
a magnetic field in which the coil means is positioned, the axially movable member
being provided with pieces of magnetic material which are disposed in said magnetic
field so that the latter exerts a force which urges the axially movable member towards
a neutral axial position, characterised in that the pieces of magnetic material are
disposed adjacent axially opposite ends of the axially movable member so that there
is a substantially linear relationship between the said force and the movement of
the axially movable member.
[0008] The magnetic circuit means may comprise one or more permanent magnets and one or
more yokes of magnetically permeable material, the yoke or yokes being disposed radially
inwardly and/or radially outwardly of the axially movable member. Thus there may be
both an inner yoke and an outer yoke or, alternatively, one single yoke may be provided.
[0009] Preferably, the or each magnet is disposed between a said yoke and the axially movable
member.
[0010] Preferably, the said member is both axially movable and rotatable, the said member
carrying an objective lens which is radially spaced from the shaft, the said member
being provided with tracking means for moving the said member circumferentially so
as to effect tracking of the objective lens.
[0011] In its preferred form, the apparatus of the present invention thus requires no space
for a spring to be used for focusing, is easily manufactured, and exhibits excellent
temperature characteristics, thereby overcoming the problems of the known apparatus
referred to above.
[0012] The present invention is based on the principle that a piece of magnetic material,
when placed in a magnetic field which has non-uniform magnetic field distribution,
is subjected to a force acting in the direction in which the potential energy of the
piece of magnetic material becomes stable, and utilizes this force as a spring force
employed for focusing.
[0013] In the preferred construction, a number of pieces of magnetic material are attached
to the peripheral portion of an objective lens retaining holder such that they are
disposed at the centre or near the ends of two magnetic gaps as viewed in the axial
direction. The magnetic gaps form a magnetic field in which the magnetic flux density
is at a maximum at the centre and gradually decreases farther from the centre owing
to leakage flux. In consequence, when the objective lens retaining holder slides in
the focusing (i.e. the axial) direction and the pieces of magnetic material are located
apart from the centre, they are subjected to a force which tends to pull them back
into the magnetic gaps. This force constitutes a magnetic spring force in the focusing
direction.
[0014] The invention is illustrated, merely by way of example, in the accompanying drawings,
in which:-
Figure 1 is a perspective view of a first embodiment of an apparatus of the present
invention,
Figure 2 is a perspective view of a known apparatus having a rubber spring,
Figure 3 is a side cross-sectional view illustrating the magnetic field distribution
in a magnetic gap which is obtained in the first embodiment of the present invention;
Figure 4 is a side cross-sectional view illustrating the position of pieces of magnetic
material employed in the first embodiment of the present invention,
Figure 5a is a graph illustrating the magnetic spring force acting in the focusing
direction if a piece of magnetic material is provided at the centre, as opposed to
the ends, of the gap shown in Figure 4,
Figure 5b is a graph illustrating the magnetic spring force acting in the focusing
direction, when pieces of magnetic material are provided at the upper and lower ends
of the gap shown in Figure 4,
Figure 6 is a perspective view of a second embodiment of an apparatus according to
the present invention,
Figure 7 is a side cross-sectional view illustrating the magnetic field distribution
in a magnetic gap which is obtained in another embodiment of the present invention,
and
Figure 8 shows the results of measurement of the frequency characteristics obtained
in the various embodiments of the present invention.
[0015] Terms such as "upward" and "downward", as used in the description below, are to be
understood to refer to directions as seen in the accompanying drawings.
[0016] Referring first to Figure 1, an objective lens retaining holder 1 has a tubular portion
1a and a diametrically extending arm 1b which extends radially outwardly of the tubular
portion 1a on diametrically opposite sides of the latter. The arm 1b is provided with
an objective lens 2. The tubular portion 1a is provided with a focusing coil 3 for
adjusting focusing, tracking coils 4 for adjusting tracking, and two pieces of magnetically
permeable material 11, e.g. unmagnetised iron or nickel. The holder 1 can be rotated
about a supporting shaft 7 and can be slid in the axial direction of the supporting
shaft 7. As will be appreciated, the objective lens 2 is radially spaced from the
shaft 7. The focusing coil 3 and the tracking coils 4 are mounted on the outer surface
of the tubular portion 1a and are insulated from each other.
[0017] An outer yoke 8 of magnetically permeable material has a plate 8a which is mounted
beneath the holder 1. The outer yoke 8 has two spaced apart blocks 8b which are mounted
on or integral with the plate 8a and each of which is disposed radially outwardly
of and is spaced from the tubular portion 1a.
[0018] An inner yoke 5 of magnetically permeable material comprises two spaced apart blocks
5a which are mounted on or are integral with the plate 8a. The blocks 5a are respectively
disposed within slots 1c in the holder 1, the slots 1c being formed between the tubular
portion 1a and the arm 1b. The blocks 5a are radially spaced from the tubular portion
1a.
[0019] Each of the blocks 8b of the outer yoke 8 carries on its radially inner side a permanent
magnet 6 which, as shown in Figure 3, is radially spaced from the respective block
5a of the inner yoke 5 so as to provide a space 12 therebetween. The tubular portion
1a is mounted in the space 12 so as to provide an outer magnetic gap 13 (Figure 4)
between the magnets 6 and the tubular portion 1a and an inner magnetic gap 14 (Figure
4) between the blocks 5a and the tubular portion 1a, the pieces of magnetic material
11 being disposed within the outer magnetic gap 13.
[0020] Figure 3 shows the magnetic field distribution in the space 12. The lines with arrows
adjacent one end thereof indicate lines of magnetic force. The density of these lines
of magnetic force represents the intensity of the magnetic field. Points of equal
magnetic field intensity are connected with solid lines to show the magnetic field
distribution. In the space 12, the magnetic flux density is at a maximum at the centre
and decreases as it goes away from the centre due to leakage flux, as can be seen
in Figure 3.
[0021] The apparatus shown in Figure 4 has two pieces of magnetic material 11 which are
respectively provided at the upper and lower ends of the outer magnetic gap 13. This
provides a magnetic spring for use in focusing which has further linear characteristics.
Thus in the Figure 4 construction, the pieces of magnetic material 11 are respectively
disposed at positions at which they are subjected to substantially equal and opposite
magnetic forces acting in the axial direction when the objective lens retaining holder
1 is in the neutral axial position. Thus, as shown in Figure 4, they may be disposed
adjacent axially opposite ends of the objective lens retaining holder 1.
[0022] Figures 5a and 5b are graphs illustrating how the spring force is made linear by
providing the pieces of magnetic material 11 at the upper and lower ends of the outer
magnetic gap 13. As shown in Figure 5a, the spring force FA shows non-linear characteristics,
strictly speaking, if a single piece of magnetic material 11 were to be provided only
at the centre of the outer magnetic gap 13. A linear spring force Fc for focusing,
such as the one shown by the solid line in Figure 5b, is, however, available when
the magnetic spring forces provided by the two pieces of magnetic material 11 mounted
at the upper and lower ends of the outer magnetic gap 13, which are shown in Figure
5b by broken lines Fu and chain lines F1 respectively, are combined. In Figures 5a
and 5b the vertical axis F relates to the magnetic spring force in the focusing direction
and the horizontal axis X relates to the position of the tubular portion 1a in the
focusing direction.
[0023] Figure 6 is a perspective view of an apparatus according to the present invention
with pieces of magnetic material 11 provided at the upper and lower ends of the outer
magnetic gap 13. Figure 6 will not be described in detail since it is generally similar
to Figure 1.
[0024] A magnetic spring acting in the focusing direction can similarly be formed in an
apparatus which does not have the inner yoke 5. Figure 7 is a side cross-sectional
view illustrating the magnetic field distribution in a magnetic gap 15 in this case.
The lines with arrows provided adjacent one end thereof indicate lines of magnetic
force. The solid lines connect the points of equal intensity of the magnetic field.
Although the magnetic field distribution when there is no inner yoke 5 is slightly
different from the one shown in Figure 3, it is possible to form substantially the
same magnetic spring for focusing.
[0025] The embodiments of the invention shown in the drawings employ pieces of magnetic
material 11 having a rectangular configuration. However, the pieces of magnetic material
11 may be round in shape, or may be shaped in the form of a ring which can be fitted
or attached to the objective lens retaining holder 1. They may also be shaped into
rectangles which have longer sides in the axial direction, or into arcuate members
having longer sides of the circumferential than in the axial direction.
[0026] Figure 0 is a graph illustrating the frequency characteristics obtained in an apparatus
in accordance with any of the embodiments mentioned above. This graph shows that no
harmonics of vibrations are generated and that excellent spring characteristics are
available.
[0027] As is clear from the foregoing description, a magnetic spring for use in focusing
can be provided simply by attaching pieces of magnetic material 11 to opposite ends
of the objective lens retaining holder 1. In consequence, the space required for the
rubber spring in the known apparatus can be eliminated, thereby contributing to a
reduction in the size of the apparatus.
[0028] In contrast to the present invention in Figure 2 there is shown a known optical pick-up
in which focusing and tracking are performed by sliding a lens in the axial direction
and by rotating it about a shaft respectively.
[0029] In the construction of Figure 2, one end of a rubber spring 21 is fixed to a pin
23 which is set in a fixed portion of the apparatus such as a yoke, and the other
end of the rubber spring 21 is fixed through a pin 22 to the objective lens retaining
holder 1 which constitutes a movable portion. In consequence, when the objective lens
moves in the focusing direction indicated by A, the objective lens 2 is retained in
a given axial position by the resilient force of the rubber spring 21, thereby maintaining
the focusing staiblity.
[0030] However, when such retention is performed by a rubber spring, since it is difficult
to mount the latter accurately without distorting the rubber, the spring action may
not be linear. On the contrary, it is relatively easy in the case of the present invention
to attach the piece or pieces of magnetic material 11 to the objective lens retaining
holder 1 with accuracy, and the magnetic spring so obtained is therefore almost free
from such problems.
[0031] Since the magnetic spring employed in the present invention, moreover, utilizes a
magnetic action, it has excellent temperature characteristics, compared with the known
rubber spring.
1. Apparatus for urging an axially movable member towards a neutral axial position, the
apparatus comprising an axially movable member (1) which is axially movable over a
shaft (7); coil means (3) mounted on the axially movable member (1) for adjusting
the axial position of the latter; and magnetic circuit means (5,6,8) for generating
a magnetic field in which the coil means (3) is positioned, the axially movable member
(1) being provided with pieces of magnetic material (11) which are disposed in said
magnetic field so that the latter exerts a force which urges the axially movable member
(1) towards a neutral axial position, the apparatus being characterised in that the
pieces of magnetic material (11) are disposed adjacent axially opposite ends of the
axially movable member (1) so that there is a substantially linear relationship (Fc)
between the said force and the movement of the axially movable member (1).
2. Apparatus as claimed in claim 1 characterised in that the magnetic circuit means (5,6,8)
comprises one or more permanent magnets (6) and one or more yokes (5,8) of magnetically
permeable material, the yoke or yokes (5,8) being disposed radially inwardly and/or
outwardly of the axially movable member (1).
3. Apparatus as claimed in claim 2 characterised in that there is both an inner yoke
(5) and an outer yoke (8).
4. Apparatus as claimed in claim 2 characterised in that one single yoke (5,8) is provided.
5. Apparatus as claimed in any of claims 2-4 characterised in that the or each magnet
(6) is disposed between a said yoke (5,8) and the axially movable member (1).
6. Apparatus as claimed in any preceding claim characterised in that the said member
(1) is both axially movable and rotatable, the said member (1) carrying an objective
lens (2) which is radially spaced from the shaft (7), the said member (1) being provided
with tracking means (4) for moving the said member (1) circumferentially so as to
effect tracking of the objective lens (2).
1. Dispositif pour solliciter une pièce mobile en direction axiale vers une position
axiale neutre, ce dispositif comprenant une pièce mobile en direction axiale (1) qui
peut être déplacée axialement sur un axe (7); une bobine (3) montée sur la pièce mobile
en direction axiale (1) pour régler la position axiale de cette dernière; et un circuit
magnétique (5, 6, 8) destiné à produire un champ magnétique dans lequel la bobine
(3) est placée, la pièce mobile en direction axiale (1) comportant des éléments en
matériau magnétique (11) qui sont disposés dans le champ magnétique, de façon que
ce dernier exerce une force qui sollicite la pièce mobile en direction axiale (1)
vers une position axiale neutre, le dispositif étant caractérisé en ce que les éléments
en matériau magnétique (11) sont disposés dans des positions adjacentes aux extrémités
opposées en direction axiale de la pièce mobile en direction axiale (1), de façon
qu'il y ait une relation pratiquement linéaire (Fc) entre la force précitée et le
mouvement de la pièce mobile en direction axiale.
2. Dispositif selon la revendication 1, caractérisé en ce que le circuit magnétique (5,
6, 8) comprend un ou plusieurs aimants permanents (6) et une ou plusieurs culasses
(5, 8) en un matériau à perméabilité magnétique élevée, la culasse ou les culasses
étant disposées radialement du côté intérieur et/ou du côté extérieur de la pièce
mobile en direction axiale (1).
3. Dispositif selon la revendication 2, caractérisé en ce qu'il comporte à la fois une
culasse intérieure (5) et une culasse extérieure (8).
4. Dispositif selon la revendication 2, caractérisé en ce qu'il comporte une seule culasse
(5, 8).
5. Dispositif selon l'une quelconque des revendications 2-4, caractérisé en ce que l'aimant
ou chaque aimant (6) est placé entre l'une des culasses précitées (5, 8) et la pièce
mobile en direction axiale (1).
6. Dispositif selon l'une quelconque des revendications précédentes, caractérisé en ce
que la pièce précitée (1) est à la fois mobile en direction axiale et en rotation,
cette pièce porte un objectif optique (2) qui est placé à une certaine distance radiale
de l'axe (7), et cette pièce (1) comporte des moyens de poursuite (4) qui sont destinés
à déplacer la pièce (1) en rotation pour faire en sorte que l'objectif optique (2)
effectue un mouvement de poursuite.
1. Vorrichtung zur Positionierung eines axial beweglichen Elementes in eine neutrale
axiale Position, umfassend ein auf einem Schaft (7) axial bewegliches Element (1),
eine an dem axial beweglichen Element (1) angebrachte Spuleneinrichtung (3) zur Einstellung
der axialen Position des axial beweglichen Elementes (1) und Mittel (5, 6, 8) zur
Bildung eines magnetischen Kreises für die Erzeugung eines Magnetfeldes, in dem die
Spuleneinrichtung (3) positioniert ist, wobei das axial bewegliche Element (1) mit
Stücken aus magnetischem Material (11) versehen ist, die in dem magnetischen Feld
angeordnet sind, so daß letzteres eine das axial bewegliche Element (1) zu einer neutralen
axialen Position hin drängende Kaft ausübt,
dadurch gekennzeichnet,
daß die Stücke aus magnetischem Material (11) in der Nähe axial einander gegenüberliegender
Enden des axial beweglichen Elementes (1) angeordnet sind, so daß zwischen der genannten
Kraft und der Bewegung des axial beweglichen Elementes (1) eine im wesentlichen lineare
Beziehung besteht.
2. Vorrichtung nach Anspruch 1,
dadurch gekennzeichnet, daß die Mittel (5, 6, 8) zur Bildung eines magnetischen Kreises einen oder mehrere
Permanentmagneten (6) und ein oder mehrere Joche (5, 8) aus magnetisch permeablem
Material umfassen, wobei das Joch bzw. die Joche (5, 8) radial innerhalb und/oder
radial außerhalb des axial beweglichen Elementes (1) angeordnet sind.
3. Vorrichtung nach Anspruch 2,
dadurch gekennzeichnet, daß sowohl ein inneres Joch (5) als auch ein äußeres Joch (8) vorgesehen ist.
4. Vorrichtung nach Anspruch 2,
dadurch gekennzeichnet, daß ein einzelnes Joch (5, 8) vorgesehen ist.
5. Vorrichtung nach wenigstens einem der Ansprüche 2 bis 4,
dadurch gekennzeichnet, daß der Magnet (6) bzw. jeder Magnet (6) zwischen einem Joch (5, 8) und dem axial
beweglichen Element (1) angeordnet ist.
6. Vorrichtung nach wenigstens einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, daß das Element (1) sowohl axial beweglich als auch drehbar ist, daß das Element
(1) eine Objektivlinse (2) trägt, die einen radialen Abstand von dem Schaft (7) hat,
und daß das Element (1) mit Abgleichmitteln (4) zwecks Bewirkung einer Umfangsbewegung
des Elementes (1) zum Abgleich bzw. zur Nachführung der Objektivlinse (2) versehen
ist.